System for on-chip temperature measurement in integrated circuits

ABSTRACT

A thermal sensor providing simultaneous measurement of two diodes. A first diode and a second diode are coupled to a first current source and a second current source, respectively. The ratio of the currents provided by the two sources is accurately known. The voltage across each of the two diodes may be coupled to the input of a differential amplifier for determination of temperature. Alternatively, the first diode may be coupled to a first current source by a resistor with a known voltage drop, and the second diode may be coupled to an adjustable second current source. The current in the second diode may be adjusted until the voltage across the second diode is equal to the sum of voltage drop across the first diode and the known voltage drop across the resistor. Under the established conditions, the Diode Equation may be used to calculate a temperature.

FIELD OF THE INVENTION

Embodiments of the present invention relate to temperature measurement of integrated circuits. In particular, embodiments of the present invention relate to an on-chip temperature sensor for integrated circuits.

BACKGROUND ART

Temperature measurement in semiconductor devices such as integrated circuits on silicon substrates is often done by taking advantage of the fundamental relationship between the saturation current of a p-n junction and its temperature. This relationship is described by the Diode Equation shown below: I=I _(S)*[exp(qV/nkT)−1] where,

-   -   I_(S)=saturation current     -   q=electron charge     -   V=p-n junction voltage     -   n=ideality factor (between 1 and 2)     -   k=Boltzmann's constant     -   T=absolute temperature (K)

The ideality factor n is equal to 2 for pure recombination current (low voltage, low current density), and equal to 1 for pure diffusion current (higher voltages). When using a p-n junction as a temperature sensor, it is desirable that n be close to 1. However, high current densities should be avoided to minimize ohmic effects due to series resistances outside of the p-n junction. Ohmic effects can lead to a deviation from the Diode Equation.

FIG. 1 shows a conventional thermal sensor 100. A current source 105 with a single diode 110 is used, with sequential measurements being taken for current and voltage to obtain two I-V data pairs (I₁, V₁) and (I₂, V₂) for the diode 110. The temperature T is then calculated (neglecting the −1) from the Diode Equation as follows: T=(q/nk)*(V ₂ −V ₁)/(ln(I ₂ /I ₁)) The (−1) term in the Diode Equation may be ignored since the resulting error is usually less than 1 part in 100,000 for all current densities of interest.

In conventional temperature measurements made using a single diode, there are a number of error sources that reduce the accuracy and reliability of the measurements. Also, the sequential measurements reduce the frequency with which measurements can be made.

In the measurement of the two voltages, the error associated with each individual measurement contributes to the total error for the term (V₂−V₁). Since this term is normally quite small (about one tenth of V₂ or V₁), the accuracy of the voltage measurements is critical. Also, voltage measurements usually involve an analog-to-digital conversion, with an associated quantization error that is counted twice.

Another source of error are leakage currents. For example, shunt resistance 120 may produce a deviation from the I-V characteristic expressed by the Diode Equation. Also, since the measurements are sequential, short term changes in the circuit state can affect the measurements. As previously described, a series resistance 115 may also introduce error.

SUMMARY OF INVENTION

Thus, a need exists for a more accurate temperature sensor for integrated circuits. There is also a need for a temperature sensor that eliminates the problems associated with sequential electrical measurements, as well as providing reduced errors, reduced noise, and an increased measurement frequency.

Accordingly, embodiments of the present invention provide on-chip temperature sensing through simultaneous electrical measurement of a plurality of diodes. The simultaneous measurement of more than one diode eliminates the need for sequential measurements and reduces quantization error.

In an embodiment of the present invention, two diodes are each coupled to a controlled current source. The ratio of the currents provided by the two sources is accurately known. The voltage across each of the two diodes is coupled to the input of a differential amplifier. The output of the differential amplifier may be coupled to an analog-to-digital converter.

In another embodiment, a first diode is coupled to a first current source by a resistor with a known voltage drop, and a second diode is coupled to an adjustable second current source. The current in the second diode is adjusted until the voltage across the second diode is equal to the sum of voltage drop across the first diode and the known voltage drop across the resistor. Under the established conditions, the Diode Equation may be used to calculate a temperature.

Although the above embodiments describe the use of two diodes in parallel, three or more diodes may be used in parallel, with or without coupling resistors. The additional measurements may be used to further reduce error.

These and other objects and advantages of the present invention will no doubt become obvious to those of ordinary skill in the art after having read the following detailed description of the preferred embodiments which are illustrated in the various drawing figures.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. The drawings referred to in this description should not be understood as being drawn to scale except if specifically noted.

Prior Art FIG. 1 shows a thermal sensor with a single diode.

FIG. 2A shows a schematic diagram for a square layout of two diodes in accordance with an embodiment of the present claimed invention.

FIG. 2B shows a schematic diagram for an approximate circular layout of two diodes in accordance with an embodiment of the present claimed invention.

FIG. 3A shows a dual-diode thermal sensor, in accordance with an embodiment of the present claimed invention.

FIG. 3B shows a dual-diode thermal sensor with a sensing series resistor, in accordance with an embodiment of the present claimed invention.

FIG. 4 shows a current source servo controller, in accordance with an embodiment of the present claimed invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the following detailed description of the present invention, a system for on-chip temperature measurement in an integrated circuit, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be obvious to one skilled in the art that the present invention may be practiced without these specific details. In other instances well known methods involving photolithography, ion implantation, deposition and etch, etc., and well known circuit components such as current sources and amplifiers, etc., have not been described in detail so as not to unnecessarily obscure aspects of the present invention.

FIG. 2A shows a substrate layout pattern 200 for a first diode and a second diode in accordance with an embodiment of the present invention. The first diode comprises an array of discrete diode elements d1 and the second diode comprises an array of discrete diode elements d2. Separate interconnects may be fabricated to achieve parallel electrical connection between diodes d1, and between diodes d2.

In general, the diode arrays d1 and d2 are preferably laid out in an area with a small area moment (e.g. a square or a circle). A compact layout on the surface of the integrated circuit minimizes the overall spatially related variations between the diodes. It is also desirable that each of the diode arrays have a common centroid.

In a preferred embodiment, the exemplary pattern of FIG. 2A comprises 128 d1 diodes and 128 d2 diodes laid out in a square with a dimension of about 85 microns.

In achieving the desired layout, a sub-array 201 that has a common centroid and compact area, may be used as a tile to build the overall area for the two diodes.

FIG. 2B shows an approximate circular substrate layout pattern 205 that comprises the sub-array 201 of FIG. 2A. It is desirable that the total diode array have a shape that has two or more axes of symmetry.

FIG. 3A shows a dual-diode thermal sensor 300, in accordance with an embodiment of the present invention. The sensor 300 comprises a controller 315 for controlling the current output of a first current source 305 and a second current source 310. The first current source 305 is coupled to a first diode 320, and the second current source 310 is coupled to a second diode 325. Both diode 320 and diode 325 are coupled to ground.

The output ratio of current source 310 to current source 305 is fixed (I2=K*I1) within the range used for measurement, thereby eliminating the variable (I₂/I₁) term from the Diode Equation. Each of the current sources 305 and 310 may comprise an array of current source elements, wherein the arrays share a common centroid.

The voltage drop across each of the diodes 320 and 325 are input to a differential amplifier that in turn drives an analog-to-digital converter (ADC). Since voltage measurements are made simultaneously and the difference is quantized, only one quantization error is involved in the measurement.

FIG. 3B shows a dual-diode thermal sensor with a sensing series resistor 335, in accordance with an embodiment of the present invention. The output of Controller 315 controls current source 306 and current source 311. Current source 306 and current source 311 each comprises M and N identical small current source elements (iLSB), respectively. In this particular embodiment N is programmable, whereas M is fixed. However, in other embodiments, M may also be programmable.

The controller 315 controls the current level for each of the iLSB current sources that make up sources 306 and 311, and may also control the number of iLSB current sources that are active.

Similarly, resistor R1 335 may be made up of a number of identical small resistors (rLSB). Resistor R1 may be implemented as a programmable resistor by bypass switches (e.g., transistors with low R_(ds) on) for one or more of the rLSB resistors. In this particular embodiment, R1 is considered as having a fixed value, with R rLSB resistors in series.

A high-gain op amp (comparator) 340 is coupled to receive V_(A) and V₂ as inputs. V_(A) is the sum of the voltage drops across resistor R1 and diode D1 320, and V₂ is the voltage drop across diode D2 325. The output of the comparator is coupled to a processor 345 that determines the diode temperature from the value of N established by controller 315, and a set of circuit parameters. N may be adjusted by the controller 315 until the comparator 340 switches, thus establishing the point at which V_(A)=V₂.

Since the entire thermometer 301 may fabricated on-chip, the negative impact of series resistances may be reduced considerably. The on-chip thermometer may also be tested and adjusted to compensate for observed deviations in temperature readings.

In testing, the temperature determined by the processor may be compared to the known value of the integrated circuit during test. A fuse array 350 may be used to program a correction that may be read and applied by the processor. For example an array of four fuses may provide 15 values for correction. In this case, an anticipated error range of +/−3K may thus be divided into 15 corrections that may be applied, ranging from −3K to +3K in increments of 0.4K. More fuses may be used to provide a greater range of corrections and/or a finer resolution of correction.

FIG. 4 shows a current source servo controller 400 that may be used by controller 315 for establishing the current level for each of the iLSB sources. An op amp 405 receives a precision reference voltage (e.g., bandgap reference) as one input. A second input is taken as the voltage across resistor R2 415, providing a servo loop that operates to set the current through R2 such that the voltage drop across R2 is equal to V_(ref).

In one embodiment, resistor R2 comprises a number of identical small resistors (rLSB), as are used in R1. In one embodiment, resistor R2 may be implemented as a programmable resistor by bypass switches (e.g., transistors with low R_(ds) on) for one or more of the rLSB resistors. In this particular embodiment, R2 is considered as having a fixed value, comprising S rLSB resistors in series.

The servo loop current source Iloop 410 is made up of L iLSB current sources in parallel, similar to current sources I1 and I2 of FIG. 3B. In the example of FIG. 4, op amp (operational amplifier) 405 drives a current source 406 that is mirrored by each of the iLSB current sources in Iloop, I1 and I2. Alternatively, each iLSB current source may be a voltage controlled current source that is driven by the output of op amp 405.

Taking into account the configuration of the controller of FIG. 4 and the sensor circuit of FIG. 3B, the voltage drop across resistor R1 335 may be represented as: V _(R1) =I1*R1=M*iLSB*R*rLSB=MR*(iLSB*rLSB) also, V_(R2)=Iloop*R2=L*iLSB*S*rLSB, V_(ref)=V_(R2) Giving: V _(ref) /LS=iLSB*rLSB V _(R1)=(MR/LS)*V _(ref)

It is appreciated that the voltage across R1, that is V_(R1), is a known quantity based upon the integer quantities M, R, L and S, and the reference voltage V_(ref). With this in mind, the operation of the system of FIG. 3B is described.

With reference to FIG. 3B, it is seen that since V_(A)=V_(R1)+V₁ and V_(A)=V₂, V_(R1)=V₂−V₁, which is one term required for a temperature solution based upon the Diode Equation, with the other term being the current ratio.

Referring again to FIG. 3B, N may be set equal to M by the controller 315, causing the voltage V_(A) to be greater than V₂. The programmable current source I2 311 may then be incrementally adjusted by sequentially switching in additional iLSB current sources in turn. Alternatively, a binomial search or other algorithm may be used to find the value of N at which V_(A)=V₂.

At some point, when a number J of additional iLSB sources have been switched in, V₂ will exceed V_(A), causing the comparator 340 to change state. Although the incremental nature of the current increases prevents determining the exact current at which V_(A)=V₂, a range can be established and the range midpoint used for purposes of calculation. In this case, the current may be taken as (M+J−½)iLSB.

Thus, the current ratio I₂/I₁ corresponding to the diode voltages V₁ and V₂ has been determined as (M+J−½)/M. Although a specific scheme has been presented for adjusting the current source I2 and equalizing V_(A) and V₂, other starting values and modes of adjustment may be used. Also, another value within the comparator crossover range may used for purposes of calculation.

There are many factors to be considered in the selection of the component sizes and the values of the integers L, M, R, and S. Depending upon the process used for integrated circuit fabrication and the design of the circuit, the transistors (switches and current sources), diodes and resistors of the thermal sensor may vary considerably in size and number.

It is desirable to provide a common centroid for each of the current sources Iloop, I1, and I2. The centroid applies to the layout of the arrays of iLSB sources that make up each of the current sources Iloop, I1, I2. The centroid also applies to the subset of the current sources that may be switched on at a particular time. Thus, there is both a centroid associated with layout, and a centroid associated with operation.

For example, in a circuit for which the diode current limit was desired to be about 400 microamperes, 256 iLSB current sources with a nominal current of roughly 2 to 2.5 microamperes may be used. The maximum current is related to the minimum temperature that is to be measured accurately. Since high temperature accuracy is generally more important for a circuit than low temperature accuracy, the minimum accurate temperature is selected to be about 308K to 318K. It is desired to use a sufficiently high value for N (e.g., 120 to 160) at temperatures of interest (e.g., 340K to 385K) in order to minimize the impact of quantization error.

The error in the temperature measurement will be proportional to the error in the (V₂−V₁). Therefore, it is desirable to make (V₂−V₁) as large as possible relative to the resolution of the comparator. On the other hand, I₂ and V₂ should be kept from being too large and I₁ and V₁ should be kept from being to small. In this way, deviation from the Diode Equation can be minimized, and the ideality factor n kept close to 1. In view of these considerations dV=(V₂−V₁) may be targeted to be about 0.085 volts.

It is desired that the current ratio N/M be about 18 for the lowest temperature of interest: N/M=exp((q*dV)/(k*T_(min))), where N=160, corresponding to the T_(min) of interest. Using dV=0.085 V, T_(min)=340K, we get N/M=18.2, M=160/18.2=8.8, giving 9 for the fixed integer value of M.

The V_(ref) level may be obtained from a bandgap reference. In order to reduce noise in reference signal, a voltage divider using two high value resistors may be used to divide the bandgap voltage. For example, two matched resistors may be used to divide a bandgap voltage of 1.175 volts in half to provide a V_(ref)=0.5875 volts. The divider output may use a shunt capacitor to filter high frequency noise. The sensor circuit servo may be used to filter low frequency noise.

The relationships for S, L and R may now be examined. From above, SL=MR*(V_(ref)/dV)=R1*62.2. To avoid having to make S and L too large, it is preferred that R be set close to 1. Using S=L=8, we get even numbers that help the centroiding for the resistors.

The calculated dV is then: dV=(MR/SL)*vRef=0.0826 V. Finally, a nominal value for rLSB is determined from rLSB=dV/(M*iLSB); using a nominal value of 2.0 microamperes for iLSB, rLSB=4.6 kohm. Thus, the solution for T from the Diode Equation becomes:

$\begin{matrix} {T = {\left( {q/{nk}} \right)*{{dV}/{\ln\left( {{i2}/{i1}} \right)}}}} \\ {= {\left( {q/{nk}} \right)*\left( {\left( {{MR}*{V_{ref}/{SL}}} \right)/{\ln\left( {N/M} \right)}} \right)}} \\ {= {11600\mspace{20mu}{K/V}*{\left( {9*{\left( {1.175{V/2}} \right)/64}} \right)/{\ln\left( {N/9} \right)}}}} \\ {= {958.4/{{\ln\left( {N/9} \right)}.}}} \end{matrix}$

TABLE 1 TEMPERATURE N*iLSB (K.) N (microamperes) 398.0 100 218 396.4 101 220 370.0 120 258 368.8 121 260 333.7 159 336 333.0 160 338 309.0 200 418 308.5 201 420

Table 1 shows the calculated temperature for different values of N in accordance with the above solution for T. The step from N=100 to N=101 corresponds to a change in temperature from 398K to 396.4K, or a difference of 1.6K. In keeping with the practice of taking the midpoint of the interval in which the comparator changes state, the temperature measurement for this interval would be 397.2K, with a quantization error of +/−0.8K.

Although the quantization error for the interval between N=200 and N=201 is smaller than that for the interval for N=100 to N=101, it should be noted that the diode current is over 400 microamperes, and ohmic effects may affect the overall accuracy.

Although the simultaneous use of two diodes obviates the need for sequential measurements, the system of the present invention may be used to make sequential measurements using two different current levels. Thus, temperature measurements may be made in a conventional timeframe, but with increased accuracy.

In general, the accuracy requirement for temperature measurements on integrated circuits is on the order of +/−3K. Although the quantization may be reduced by using a 9-bit digital-to-analog converter (DAC) instead of the 8-bit DAC (256 iLSB sources) described herein, the quantization error of 0.8K is already low with respect to industry standards for overall accuracy.

The foregoing descriptions of specific embodiments of the present invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the Claims appended hereto and their equivalents. 

1. A system for measuring a temperature in an integrated circuit comprising: a first diode coupled to a first current source; a second diode coupled to a second current source; a controller coupled to said first and second current sources for controlling a current output of said first current source and a current output of said second controlled current source to maintain a fixed ratio between said current output from said first current source and said current output from said second current source; and a differential amplifier coupled to said first diode and to said second diode for measuring a difference in voltage between said first diode and said second diode, wherein said difference is related to a current temperature of said integrated circuit.
 2. The system of claim 1, wherein said first diode comprises a first array of diode elements and said second diode comprises a second array of diode elements.
 3. The system of claim 2, wherein said first array of diode elements and said second array of diode elements substantially share a common centroid.
 4. The system of claim 2, wherein said first diode and said second diode occupy a substantially square region on the surface of said integrated circuit.
 5. The system of claim 1 wherein said first diode and said second diode occupy a region having at least two axes of symmetry.
 6. The system of claim 1, wherein said first current source comprises a first array of current source elements and said second current source comprises a second array of current source elements and wherein said first and second arrays of current source share a common centroid.
 7. The system of claim 1, further comprising an analog-to-digital converter (ADC) coupled to said differential amplifier.
 8. A system for measuring temperature in an integrated circuit comprising: a first current source comprising a first array of current source elements; a resistor with a predetermined voltage drop coupled to said first current source; a first diode coupled to said resistor; a programmable second current source comprising a second array of current source elements; a second diode coupled to said second current source; a comparator coupled to said resistor and to said second diode, said comparator generating a signal; and a controller coupled to said programmable second current source and said comparator, said controller generating a programming value for controlling the programmable second current source such that said signal generated by said comparator toggles between a first and second state, wherein the programming value is related to a current temperature of the integrated circuit.
 9. The system of claim 8, further comprising a processor coupled to said comparator and to said controller.
 10. The system of claim 9, further comprising a fuse array coupled to said processor.
 11. The system of claim 8, wherein said first diode comprises a first array of diode elements and said second diode comprises a second array of diode elements.
 12. The system of claim 11, wherein said first array of diode elements and said second array of diode elements share a common centroid.
 13. The system of claim 8, wherein said first current source is programmable.
 14. The system of claim 8, wherein said first array of current source elements and said second array of current source elements share a common centroid.
 15. The system of claim 14, wherein each of said current source elements of said first array and said second array mirrors a current source in said controller.
 16. The system of claim 11, wherein said controller comprises a third current source comprising a third array of current source elements.
 17. The system of claim 8, wherein the first current source and the second current source are current controlled current sources.
 18. The system of claim 8, wherein the first current source and the second current source are voltage controlled current sources. 